Filter News
Area of Research
- (-) Neutron Science (22)
- Advanced Manufacturing (3)
- Biology and Environment (16)
- Clean Energy (49)
- Computational Engineering (1)
- Computer Science (6)
- Electricity and Smart Grid (1)
- Functional Materials for Energy (1)
- Fusion and Fission (7)
- Fusion Energy (1)
- Isotope Development and Production (1)
- Isotopes (8)
- Materials (53)
- Materials Characterization (1)
- Materials for Computing (7)
- Materials Under Extremes (1)
- National Security (14)
- Nuclear Science and Technology (7)
- Quantum information Science (2)
- Supercomputing (46)
News Topics
- (-) Advanced Reactors (1)
- (-) Artificial Intelligence (1)
- (-) Biomedical (4)
- (-) Computer Science (6)
- (-) Materials Science (13)
- (-) Sustainable Energy (2)
- 3-D Printing/Advanced Manufacturing (3)
- Big Data (1)
- Bioenergy (3)
- Biology (4)
- Biotechnology (1)
- Climate Change (1)
- Composites (1)
- Coronavirus (5)
- Cybersecurity (1)
- Decarbonization (1)
- Energy Storage (2)
- Environment (4)
- Frontier (1)
- Fusion (1)
- High-Performance Computing (1)
- Materials (6)
- Microscopy (1)
- Nanotechnology (7)
- National Security (1)
- Neutron Science (43)
- Nuclear Energy (1)
- Physics (7)
- Quantum Science (5)
- Security (1)
- Space Exploration (1)
- Summit (4)
- Transportation (2)
Media Contacts
OAK RIDGE, Tenn., March 20, 2019—Direct observations of the structure and catalytic mechanism of a prototypical kinase enzyme—protein kinase A or PKA—will provide researchers and drug developers with significantly enhanced abilities to understand and treat fatal diseases and neurological disorders such as cancer, diabetes, and cystic fibrosis.
For more than 50 years, scientists have debated what turns particular oxide insulators, in which electrons barely move, into metals, in which electrons flow freely.